KR20120029345A - System and apparatus for circuit protection within an equipment enclosure - Google Patents

Abstract

PURPOSE: A system and apparatus equipped with a lacking cassette are provided to connect an arc transfer device to a power supply within a switch gear by including one or more first electrical connectors. CONSTITUTION: An arc transfer device is used with electrical equipment. One or more electrical connectors accept power from the electrical equipment. A lacking cassette(400) comprises one or more second electrical connectors. The lacking cassette comprises one or more lacking members which includes a slot for accepting one or more connectors. The second electrical connector connects a first electrical connector to the electrical equipment based on a racking position of the arc transfer device. The first electrical connector comprises one or more first main connectors and first sub connectors. The second electrical connector comprises one or more second main connectors and second sub connectors.

Description

SYSTEM AND APPARATUS FOR PROTECTION OF CIRCUITS IN EQUIPMENT CLOSURES

Embodiments described herein relate generally to power equipment protection devices and, more particularly, to systems and apparatus for use in the event of arcing.

Known power circuits and switchgears generally have conductors separated by insulators such as air, gas or solid dielectrics. However, if the conductors are placed too close to each other, or if the voltage between the conductors exceeds the insulating properties between the conductors, an arc can occur. The insulator between the conductors can be ionized, which makes the insulator conductive and forms an arc flash.

Arc flash provides rapid release of energy due to faults between two phase conductors, a phase conductor and a neutral conductor, or between one phase conductor and ground point Caused by The temperature of the arc flash can reach or exceed 20,000 ° C., which is the temperature at which the conductor and adjacent equipment can be vaporized. Moreover, the arc flash can emit sufficient energy in the form of heat, strong light, pressure waves and / or sound waves to damage the receptor and adjacent equipment. However, the current level of the fault causing the arc flash is generally lower than the current level of the short circuit, so unless the circuit breaker is specifically designed to handle the fault condition, the circuit breaker may not trip or may indicate a delayed trip. have. Although agencies and standards exist that control the arc flash problem by requiring the use of personal protective clothing and equipment, no device has been established by regulations that eliminate arc flash.

Standard circuit protection devices, such as fuses and circuit breakers, generally do not respond fast enough to mitigate arc flash. One known circuit protection device that exhibits a sufficiently rapid response is an electrical “bracket” utilizing mechanical and / or electro-mechanical processes by intentionally creating an electrical “short circuit” to convert electrical energy away from the arc flash point. crow bar) ". This intentional short circuit failure is eliminated by tripping the fuse or circuit breaker. However, intentional short circuit failures generated using crowbars allow a significant level of current to flow through adjacent electrical equipment, and the equipment can still be damaged.

Another known circuit protection device that exhibits a sufficiently rapid response is an arc receiving device, which generates a received arc and converts electrical energy away from the arc flash point. At least some known arc receiving devices are racked into the equipment enclosure using a racking frame that allows the arc receiving device to be fully inserted and activated or fully recovered and deactivated. However, this configuration renders the arc receiving device unavailable in test mode. Moreover, this configuration does not allow the arc receiving device to be inserted or removed from the live bus to avoid closing the entire set of electronic modules or equipment.

In one embodiment, an arc transport device is provided for use with electrical equipment. The arc transfer device comprises at least one electrical connector configured to receive power from the electrical equipment and at least one second configured to electrically connect the at least one first electrical connector to the electrical equipment based on the racking position of the arc transfer device. And a racking cassette comprising an electrical connector.

In another embodiment, a circuit protection system for use with a circuit is provided. The circuit protection system includes a controller configured to detect an arc flash event in a circuit and an arc receiving device operatively coupled with the controller and configured to generate an arc upon detection of an arc flash event. The arc receiving device comprises a racking cassette that facilitates racking the arc receiving device in a plurality of locations, each of the plurality of locations being associated with an operating state of the arc receiving device.

In another embodiment, the switchgear stack includes at least one circuit and a circuit protection system coupled with the circuit. The circuit protection system includes a controller configured to detect an arc flash event in a circuit, an arc receiving device and a racking cassette configured to initiate an arc in response to the detection of an arc flash event. The racking cassette includes at least one racking member configured to engage the arc receiving device and a shaft engaged with the racking member and configured to drive the racking member in one of the first and second directions based on the racking position of the arc receiving device. .

1 is a front view of an exemplary switchgear stack including a circuit protection device.
FIG. 2 is a perspective view of an exemplary arc receiving device that may be used with the circuit protection system shown in FIG. 1. FIG.
3 is a cross-sectional view of the arc receiving device shown in FIG. 2.
4 is a perspective view of one embodiment of a racking cassette that may be used with the circuit protection system shown in FIG.
5 is a perspective view of another embodiment of a racking cassette that may be used with the circuit protection system shown in FIG.
6 is a schematic perspective view of the circuit protection system shown in FIG. 1 configured for use with the racking cassette shown in FIG.
FIG. 7 is a schematic perspective view of the circuit protection system shown in FIG. 1 in a first or “orphaned” position. FIG.
8 is a schematic perspective view of the circuit protection system shown in FIG. 1 in a second or "test"position;
9 is a schematic perspective view of the circuit protection system shown in FIG. 1 in a third or "connected"position;

Exemplary embodiments of systems and apparatuses for use with circuit protection devices are described herein. These embodiments facilitate racking, such as positioning, by inserting or retracting the arc receiving device into one of a plurality of locations within an equipment closure, such as a circuit breaker cubicle. Racking the arc receiving device in multiple locations, such as a plurality of racking positions including disconnection, test or connection locations, results in complete removal of the arc receiving device in the replacement case or partial removal of the arc receiving device for service or testing. Becomes easy.

1 is a front view of an exemplary switchgear stack 100 housed in an equipment enclosure 102. The switchgear 100 includes one or more electronic modules 104 and a circuit protection system 106 that provides the electronic module 104 with protection, for example, from an arc flash event. The closure 102 includes a plurality of compartments including an upper compartment 112 that houses the electronic module 104, a central compartment 110 that accommodates the circuit protection system 106, and a lower compartment 108. Notably, the circuit protection device 106 includes an arc transfer device (not shown in FIG. 1) that transfers energy away from the detected arc flash event in the circuit, such as the electronic module 104 or power feed. The arc conveying device may be an arc receiving device described in more detail below. Optionally, the arc receiving device can be a bolted fault device that transfers the energy associated with the arc flash event to another location for dissipation in any suitable way. In addition, the closure 102 may have three or more or fewer compartments.

2 is a schematic perspective view of an exemplary arc receiving device 200 that may be used with a circuit protection system 106 (shown in FIG. 1), and FIG. 3 is a schematic cross-sectional view of the arc receiving device 200. In the exemplary embodiment, the arc receiving device 200 includes a top cover 202 and a conductor assembly 204. The conductor assembly 204 has a conductor cover 208 and a conductor base 206 between which a plurality of electrical conductors (not shown) are located. Each electrical conductor is coupled with the electrode holder 210, and each electrode holder 210 is configured to support the electrode 214. For example, the electrode 214 may be movably fixed within the fixing portion 212 of the electrode holder 210. The electrodes 214 are oriented along the plane such that each electrode 214 is located approximately equidistant from the axis from which the plasma gun (not shown) emits ablation plasma. The plasma gun is covered by a plasma gun cover 216.

In an exemplary embodiment, the top cover 202 defines the main chamber 218. Within this chamber 218 an electrode 214 generates an arc for use in dissipating energy associated with the arc flash event sensed on the circuit. Top cover 202 has a top surface 220, a lip 222, and a side surface 224 extending between the top surface 220 and the lip 222.

4 is a perspective view of one embodiment of a ranking cassette 300 that may be used with the circuit protection system 106. The racking cassette 300 has a frame 302 configured to support the arc receiving device 200. The frame 302 has a back wall 304, an opposing front wall 306, a first side wall 308, and an opposing second side wall 310. One or more racking rollers 312 and racking member 314 are coupled to the respective side walls 308, 310 to facilitate racking of the arc receiving device 200 in a plurality of locations. A racking shaft 316 is coupled with the frame 302 and at least one main contact 318 is connected to the back wall 304 to facilitate connection to the line voltage of the switchgear 100 (shown in FIG. 1). Is provided. The racking cassette 300 also includes at least one second contact (not shown) which facilitates the connection of the switch gear 100 to the control voltage.

When the arc receiving device 200 is racked in the same position as the separated position, the roller 312 is provided with a rail (not shown) provided in the compartment of the equipment closure 102 (shown in FIG. 1). Stay on or within the corresponding set of. Moreover, both primary and secondary contacts are separated from their corresponding voltage connections. Thus, the arc receiving device 200 does not operate in the first position.

When the arc receiving device 200 was racked in a second position, such as the test position, the roller 312 moved a predetermined distance along the rail of the compartment. For example, the racking shaft 316 is rotated by a predetermined amount or to a predetermined point, so that the roller 312 is advanced along the rail of the compartment. Moreover, in this second position the racking member 314 is partially engaged with a racking roller (not shown) provided in the compartment. In addition, the main contact 318 is separated from the line voltage of the switchgear 100, and the second contact is connected to the control voltage of the switchgear 100. Thus, when the arc receiving device 200 is racked in the second position, a controller (not shown) may be used to verify the circuit elements and / or plasma gun operation within the arc receiving device 200.

When the arc receiving device 200 was racked in a third position, such as a connecting position, the roller 312 moved an additional distance along the compartment rail. For example, the racking shaft 316 was rotated by an additional predetermined amount or to a different predetermined point to advance the roller 312 along the rail of the compartment. Moreover, in the second position the racking member 314 is fully engaged with the racking roller provided in the compartment. The main contact portion 318 is connected to the line voltage of the switchgear 100, and the second contact portion is connected to the control voltage of the switchgear 100. Thus, the arc receiving device 200 is fully operational when the arc receiving device 200 is locked in the third position.

5 is a schematic perspective view of another exemplary racking cassette 400 that may be used with the circuit protection system 106 (shown in FIG. 1). 6 is a schematic perspective view of a circuit protection system 106 configured for use with the racking cassette 400. The racking cassette 400 supports the arc receiving device [200 shown in FIGS. 2 and 3], thereby placing the circuit protection system 106 in an equipment rack (not shown) in a closure 102 (shown in FIG. 1). Not easy to racking). In an exemplary embodiment, the racking cassette 400 includes a bottom surface or tray 402, a first side sheet 404 and an opposite second side sheet (not shown). A back wall 406 extends between the first side sheet 404 and the second side sheet. Furthermore, the locking cassette 400 includes a plurality of protrusions 410 extending from the back wall 406 through the inner wall 408. As described in more detail below, when the arc receiving device 200 is inserted into the racking cassette 400, the protrusions 410 are pushed back to the back wall 406 to expose the second main connector. 410 may move relative to interior wall 408.

In an exemplary embodiment, the circuit protection system 106 includes a controller 500 and an arc receiving device 200. A plurality of plates including two side plates 502 and a front plate 504 are coupled to the arc receiving device 200. When inserting or removing the circuit protection system 106 from the equipment closure 102 (shown in FIG. 1), the controller 500 may include a front plate (eg, a front plate) to secure the controller 500 to the arc receiving device 200. 502). Side plates 502 are one or more sized to be inserted into or used with a racking rail (not shown) provided in a closure compartment such as a central compartment 110 (shown in FIG. 1). Roller 506.

Furthermore, the connector 508 extends through each side plate 502 and is fixed in the arc receiving device 200. For example, the connector 508 may be secured in the conductor base 210 and may be secured in the conductor cover 212 (both shown in FIGS. 2 and 3). The arc receiving device 200 also has at least one first electrical conductor. For example, arc receiving device 200 facilitates electrical connection of arc receiving device 200 to multiple conductors of a circuit (not shown) that are being protected and / or monitored by arc receiving device 200. A plurality of first main electrical connectors 510. The first primary connector 510 is a plurality of corresponding plurality located between the back wall 406 and the inner wall 408 to connect the arc receiving device 200 to the line voltage of the switchgear (shown in FIG. 1). And is coupled to a second main connector (not shown). Moreover, the controller 500 may further include a first auxiliary electrical connector 512 that facilitates connecting the controller 500 to a second auxiliary connector (not shown) for use in performing diagnostics and / or plasma gun ignition tests. ). The position indicator 514 is coupled with the top cover 202 and is oriented to engage with a switch provided in the racking cassette 400, thereby facilitating the display of the arc receiving device 200 location in the racking cassette 400. For example, the position indicator 514 has a flange 516 with one or more mounting holes 518 extending therethrough. The mounting holes 518 are sized to accommodate respective tightening mechanisms for coupling the position indicator 514 to the top cover 202. Accordingly, the top cover 202 has one or more corresponding mounting holes (not shown) located below each mounting hole 518 of the flange 516. In particular, the position indicator 514 may be coupled to any suitable portion of the arc receiving device 200 such that the switch indicates the position of the arc receiving device 200 within the racking cassette 400.

When the circuit protection system 106 is racked in a first position within the equipment rack, such as in an isolated position, the first primary connector 510 is disconnected from the second primary connector and the first secondary connector 512 is seconded. It is separated from the auxiliary connector 412. Additionally, the protrusion 410 moves forward away from the back wall 406 to shield the second main connector behind the inner wall 408. If the circuit protection system 106 is racked in an isolated position, the circuit protection system 106 may be removed from the equipment rack for service and / or replacement. Moreover, the position indicator 514 is coupled with a switch 444 provided along the first side sheet 404. The switch 444 sends a signal to the switchgear controller (not shown) indicating that the arc receiving device 200 is ready to rack. Moreover, the door (not shown) of the closure 102 may be blocked before the arc receiving device 200 is racked.

When the circuit protection system 106 is racked in a second position in the equipment rack, such as the test position, the first main connector 510 is separated from the second main connector, and the first auxiliary connector 512 is second auxiliary. Is electrically coupled with the connector 412. In particular, the second auxiliary connector 412 moves forward along the shaft 414 away from the back wall 406 to maintain electrical connection with the second auxiliary connector 512. When the circuit protection system 100 is locked in the test position, the arc receiving device 200 is in a test mode that enables testing of the device interface and signal control. For example, controller 500 is powered to test arc flash sensing components and / or to test whether the plasma gun capacitor bank is properly charged during connect mode.

When the circuit protection system 106 is racked in a third position in the equipment rack, such as a connection position, the first main connector 510 is electrically coupled with the second main connector, and the first auxiliary connector 512 is disconnected. 2 is electrically coupled with the auxiliary connector 412. In particular, the protrusion 410 is pushed back into the back wall 406 to expose the second main connector and the first main connector 510 connected thereto. When the circuit protection system 100 is locked in the connecting position, the arc receiving device 200 is active. Controller 500 to charge a plasma gun capacitor bank (not shown) used to power a plasma gun for use in initiating an arc between electrodes 214 (shown in FIGS. 2 and 3). Is powered.

Moreover, in an exemplary embodiment the racking cassette 400 has a crank mechanism 416, a plurality of first links 418, and a shaft 420. Each first link 418 is coupled to the crank mechanism 416 at the first end 422 and to the shaft 420 via each interlock 426 at the second end 424. The racking cassette 400 also includes a plurality of racking members 428 connected to the shaft 420 via respective second links 430. In particular, each second link 430 is coupled to the shaft 420 at the first end 432 and to each racking member 428 at the second end 434. Tray 402 may be inserted or removed from racking cassette 400 along side rail 436 coupled to first side sheet 404 and second side sheet. Inserting the tray 402 into the racking cassette 400 causes the crank mechanism to move the first link 418 back towards the rear wall 406. Movement of the first link 418 causes each interlock 426 to rotate, thereby causing the shaft 420 to rotate similarly clockwise. Rotation of the shaft 420 causes the second link 430 to rotate or drive each racking member 428 clockwise. Each racking member 428 includes a slot 438 sized to receive a connector 508 provided along the lateral surface of the arc receiving device 200. Rotation of the racking member 428 allows the connector 508 to move along the slot 438 toward either the rear wall 406 to either the first position or the second position. A lip 440 provided in each racking member 428 engages the connector 508 in either the first position or the second position. For example, the arc receiving device 200 is engaged in a first position when the connector 508 moves on the lip 440 toward the back wall 406. However, the arc receiving device 200 is locked in the second position when the connector 508 is positioned between the lip 440 and the end 442 of the racking member 428.

7-9 illustrate a number of locations where the circuit protection system 106 may be racked within an equipment rack provided in an equipment closure 102 (shown in FIG. 1). In particular, FIG. 7 shows the first position or the separated position, FIG. 8 shows the second position or the test position, and FIG. 9 shows the third position or the connected position.

As shown in FIG. 7, when the circuit protection system 106 is locked in the first position, the first main connector 510 is disconnected from the second main connector (not shown), and the first auxiliary connector ( 512 is separated from the second auxiliary connector 412. Likewise, the protrusion 410 moves forward away from the back wall 406 to shield the second main connector. Furthermore, when the arc receiving device 200 moves from the second or third position to the first position along the rail 436, each connector 508 is formed on the back wall 406 on the respective racking ear lip 440. Move away from Additionally, the locking member 428 rotates counterclockwise to release the connector 508 from the second position. If the circuit protection device 106 is racked in the disconnected position, the circuit protection system 106 may be removed from the equipment rack for service and / or replacement. Moreover, when initially racking the arc receiving device 200, the position indicator 514 engages the switch 444 provided along the first side seat 404.

As shown in FIG. 8, when the circuit protection system 106 is locked in the second position, the first main connector 510 is separated from the second main connector (not shown), and the first auxiliary connector 512. ) Is electrically coupled to the second auxiliary connector 412. In particular, the second auxiliary connector 412 moves forward along the shaft 414 away from the back wall 406 to maintain electrical connection with the first auxiliary connector 512. Moreover, when the circuit protection system 106 moves to the second position along the rail 436, the connector 508 moves away from the back wall 406 on each locking ear lip 440. Additionally, the racking member 428 rotates the connector 508 counterclockwise to further engage from the first position, thereby engaging the connector 508 in the second position. When the circuit protection system 106 is locked in the second position, the arc receiving device 200 is in a test mode that enables testing of the device interface and signal control. For example, controller 500 is powered to test arc flash sensing components and / or to test whether the plasma gun capacitor bank is properly charged during connect mode.

As shown in FIG. 9, when the circuit protection system 106 is locked in the third position, the first main connector 510 is electrically coupled to a second main connector (not shown), and the first auxiliary connector ( 512 is electrically coupled to the second auxiliary connector 412. Moreover, when the circuit protection system 106 moves to the third position along the rail 436, the connector 508 (shown in FIG. 6) is placed over each racking ear lip 440 (shown in FIG. 5). Respectively move towards the back wall 406. Additionally, the racking member 428 (shown in FIG. 5) rotates clockwise to engage the connector 508 in place. When the circuit protection system 106 is locked in the third position, the arc receiving device 200 is activated. For example, a plasma gun capacitor bank (not shown) used to power a plasma gun (not shown) for use in initiating an arc between electrodes 214 (not shown in FIG. 3). Power is supplied to the controller 500 to charge it.

Exemplary embodiments for use in devices for the protection of power distribution equipment are described in detail below. The apparatus is not limited to the specific embodiments described herein, but rather, the operation of the method and / or components of the system and / or apparatus may be used independently from other operations and / or components described herein. It may be. In addition, the described acts and / or components may be defined or used in combination with other systems, methods, and / or devices, and are not limited to running with the systems, methods, and storage media as described herein. Does not.

Although the invention has been described in connection with an exemplary power distribution environment, embodiments of the invention may be used in many other general or special purpose power distribution environments or configurations. This power distribution environment is not intended to suggest any limitation as to the scope of functionality or use of embodiments of the present invention. Moreover, this power distribution environment should not be construed as having any dependency or requirement on any one or combination of components shown as the exemplary operating environment.

When describing elements of an embodiment or embodiment of the invention, the articles "a", "an" and "the", "said" mean that there is one or more elements. do. The terms "comprising", "including" and "having" are intended to mean inclusively that there may be additional elements other than the listed elements.

The foregoing description is directed to those skilled in the art, including examples of disclosing the present invention including the best mode, and also making and using any device or system and performing any specified method. The example which enables to implement invention is used. The patentable scope of the invention is defined by the claims, and may include other examples made by those skilled in the art. Such other examples are considered to be within the scope of the claims if the literal representation of the claims includes structural elements that do not differ, or if the literal representation of the claims includes other equivalent structural elements. .

200: arc receiving device 400: racking cassette
428: racking member 438: slot
508: connector 514: position indicator

Claims (10)

In an arc transport device for use with electrical equipment,
At least one electrical connector configured to receive power from the electrical equipment;
A racking cassette 400 comprising at least one second electrical connector configured to electrically connect the at least one first electrical connector to the electrical equipment based on the racking position of the arc transport device.
Arc transfer device. The method of claim 1,
The arc transport device further comprises at least one connector 508, the racking cassette 400 having a slot sized to receive the at least one connector 508 based on the racking position of the arc transport device. Further comprising at least one racking member 428 comprising 438
Arc transfer device. The method of claim 2,
The racking cassette 400 further includes a crank mechanism 416 and a shaft 414, wherein the shaft 414 is coupled with the crank mechanism 416 and the at least one racking member 428, and The arc transport device is configured to be racked at a plurality of positions in the racking cassette 400.
Arc transfer device. The method of claim 1,
The at least one first electrical connector includes at least one first primary connector 510 and a first auxiliary connector 512, wherein the at least one second electrical connector includes at least one second primary connector and a first connector. 2 auxiliary connectors 412 include:
When the arc transport device is locked in the first position, the at least one first main connector 510 is separated from the at least one second main connector, and the first auxiliary connector 512 is at least one. Separate from the second auxiliary connector 412;
When the arc transport device is locked in the second position, the at least one first main connector 510 is separated from the at least one second main connector, and the first auxiliary connector 512 is connected to the second auxiliary connector. Is electrically coupled with connector 412;
When the arc transport device is locked in the third position, the at least one main connector 510 is electrically coupled with the at least one second main connector, and the first auxiliary connector 512 is connected to the second auxiliary connector. Electrically coupled with connector 412
Arc transfer device. The method of claim 4, wherein
The racking cassette 400 further includes at least one protrusion configured to expose the at least one second main connector when the arc transport device is locked in a third position.
Arc transfer device. The method of claim 5, wherein
The at least one protrusion 410 is configured to shield the at least one second main connector when the arc transport device is not racked in the third position.
Arc transfer device. The method of claim 1,
The arc transfer device includes a position indicator 514, the racking cassette 400 includes a switch 444, and the position indicator 514 is based on the racking position of the arc transfer device. And the switch 444 is configured to provide an indication of the racking position of the arc transfer device relative to the switchgear stack.
Arc transfer device. The method of claim 1,
The arc conveying device comprises an arc receiving device 200
Arc transfer device. In a circuit protection system 106 for use with a circuit,
A controller 500 configured to detect an arc flash event in the circuit;
An arc receiving device (200) operatively coupled with the controller (500) and configured to generate an arc upon detection of the arc flash event;
The arc receiving device 200 includes a racking cassette 400 that facilitates racking the arc receiving device 200 in a plurality of locations, each of the plurality of locations being in the arc receiving device 200. Related to the operating status,
Circuit protection system. The method of claim 9,
The arc receiving device 200 further includes at least one connector 508, and the racking cassette 400 includes at least one slot 438 sized to receive at least one connector 508. Comprising a locking member 428
Circuit protection system.

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